Environmental Engineering I−61350

1. An-Najah National University College of Engineering Environmental Engineering I−61350 Chapter 7 Dr. Sameer Shadeed Water Quality Sampling Dr. Sameer Shadeed

2. Introduction • The first step in water quality sampling and testing is to answer the question “Why sample and test the water?” Regular testing is the only way to know if problems exist with your water quality To help ensure you are using water suitable for your intended agricultural, industrial and recreational use To help ensure that your drinking water is safe To help determine the effectiveness of your water treatment system Dr. Sameer Shadeed

3. Sampling Objectives • The first step in developing a monitoring plan is to clearly identify the objectives of the monitoring • Water and wastewater monitoring can be undertaken to meet many objectives from gaining an understanding of an aquatic ecosystem and the physical, chemical and biological processes that operate within it, to the review of water quality within a specified criteria • Determining thesampling objectives will help determine the number of samples required, and the location and type of the samples needed • You may wish to sample for the long-term monitoring of your water quality, determine whether the water quality is generally good or bad for your intended use, or to identify specific areas of concern such as points of suspected contamination or if determining if a particular problem has been corrected Dr. Sameer Shadeed

4. Integrity of Samples • To ensure that sampling is consistent, and of good quality and traceability, samples need to be representative of the body from which they were taken • If the sample integrity is altered, the information gained from analysis could be misleading and ultimately result in mismanagement of water resources and/or polluting of the resource • The main processes that have the potential to affect the integrity of a sample are: contamination, physical and chemical changes and biological processes • These processes are interlinked and a change in one thing may have a flow-on effect that will influence another Dr. Sameer Shadeed

5. Contamination • Contamination of a sample occurs when foreign substances are introduced into it • This will lead to the sample having characteristics that are not representative of the in situ conditions • Contamination of a sample can occur at any stage of the sampling process from the collection of samples through to the final analysis, and will have a direct effect on the integrity of the sample • As many results are reported in fractions of grams, even extremely small volumes of contaminants can significantly affect results • Contamination can be very costly, especially if decisions are based on unrepresentative data Dr. Sameer Shadeed

6. Physical Changes • Any process that changes the physical nature of a sample may affect the integrity of that sample • For example • Temperature of water varies throughout the day and year • A change in temperature can alter the chemical properties of a wide range of many parameters Dr. Sameer Shadeed

7. Chemical Changes • Precipitationis the formation of solids from dissolved constituents. It can be caused by a change in conditions, such as temperature, pH, chemical concentration, or the presence of seed particles to begin the process • Oxidationis caused by the introduction of oxygen to the sample. Oxidation results in increased dissolved oxygen. Oxidation could also lower the concentrations of bulk organic parameters, chemical oxygen demand (COD) and biochemical oxygen demand (BOD), due to accelerating oxidation of organic constituents Dr. Sameer Shadeed

8. Biological Processes • Biological activity in a sample may affect both its physical and chemical characteristics • Parameters such as nitrite and nitrate can be affected by bacterial activity • Biological activity may change the amount of dissolved oxygen and the pH • Factors influencing the biological activity of a sample may in turn be influenced by temperature, available oxygen and pH • The collection, equipment and preservation methods used for sampling should be chosen to minimise the impacts of the above-mentioned factors Dr. Sameer Shadeed

9. Planning a Sampling Event • Careful planning and preparation of a sampling event is important and will save time and reduce the number of difficulties that commonly occur during sampling • The basic steps for planning a sampling event are as follows: • Review the monitoring plan, including monitoring locations, number of samples required, sampling methods • Inform the client or property owner of your intended schedule and be aware of any liabilities that you may incur • Coordinate with the analytical laboratory. Obtain appropriate sample containers. Discuss any problems you foresee, for example, with procedures, containers or limitations of reporting Dr. Sameer Shadeed

10. Planning a Sampling Event Schedule the monitoring event, including planning how and when you will transport the samples back to the laboratory. The aim is to have all samples preserved and delivered to the laboratory as quickly as possible and within recommended holding times Organize and review site maps and locations to determine logistics of sampling including sampling order Check that you have all the equipment required for the sampling event. Test that the equipment is operational and calibrated Fill out as much paperwork as practical before sampling such as preparation of labels Dr. Sameer Shadeed

11. Communication • It is strongly recommended that the analytical laboratory be consulted before implementing a sampling plan • Each laboratory may use different analytical techniques that require specific sampling techniques, preservatives or field treatments • It is important to inform the laboratory of any analytes that may be in particularly high or low concentrations • Some analytical methods need to be modified for the extremes in concentration ranges and prior knowledge of the expected range can speed up the turnaround • Some instruments may be affected if exceptionally high concentrations of certain analytes are introduced without prior dilution Dr. Sameer Shadeed

12. Communication • Factors such as salinity of a sample can also influence the choice of analytical methods, and some sample characteristics can cause interference with procedures for other analytes • During the implementation of a monitoring program it is useful to stay in communication with the laboratory so they know when to expect the samples and whether there are any problems with sample collection. This is especially important with microbiological samples Dr. Sameer Shadeed

13. Equipment • Major items of equipment likely to be needed are discussed as follows: • Paper work and record keeping:Good planning and record keeping is imperative. The sampling plan, or concise sampling schedule and map should provide all the required information such as location of monitoring points, the number and type of samples that need to be collected and container types. Records of observations and actions can be critical for future reference. A sampling data sheet is recommended to ensure that a complete record of each sampling site and event is kept Dr. Sameer Shadeed

14. Field Record Sheet (Example) Source, EPA Guidelines: Water and wastewater sampling Dr. Sameer Shadeed

15. Equipment • Navigational aids:It is important to be able to accurately locate the sampling site for future reference. A modern Global Positioning System (GPS) can be a useful aid in accurately locating a sampling site. Before attempting to navigate using GPS the sampler should be trained and competent in the use of these systems. The sampling locations should also be recorded on site maps • Field testing meters: Some analytes are most reliably determined at the point of sampling Dr. Sameer Shadeed

16. Field Testing Meters Examples of the various types of field meters available Dr. Sameer Shadeed

17. Water Sampling and Field Analysis Set Dr. Sameer Shadeed

18. Equipment • Sampling containers: As the wrong sampling equipment can affect the integrity of the sample, it is important to use appropriate sample containers for each of the various parameters. Additionally, treatments are applied to the sampling containers for some parameters to ensure sample integrity. Your analytical laboratory should be able to provide appropriate containers with required treatments • Other sampling equipment: Other forms of sampling equipment may include sampling rods, bucket and rope, depth equipment Dr. Sameer Shadeed

19. Equipment • Decontamination of sampling equipment:All sampling equipment presents a risk of cross-contamination and should be thoroughly cleaned between samples. Decontamination equipment may include detergents, ethanol, scrubbing brushes, tap water, distilled water and a receptacle for collecting waste rinse • Esky or refrigerator:Most types of sample require chilling as a means of preservation. Samples can be stored on ice in an esky or in a car refrigerator, and the temperature should be maintained between 1°C and 4°C • Camera: Photographs can show where the sample was taken and illustrate observations recorded on the field datasheet. It is good practice to take photographs on the first visit to a sampling location and when there are any unusual conditions at the site that may affect the sample Dr. Sameer Shadeed

20. Containers, Preservation Methods And Holding Times The information in the following tables is sourced from the AS/NZS 5667.1:1998. Dr. Sameer Shadeed

21. Containers, Preservation Methods And Holding Times Dr. Sameer Shadeed

22. Containers, Preservation Methods And Holding Times Dr. Sameer Shadeed

23. Containers, Preservation Methods And Holding Times Dr. Sameer Shadeed

24. Containers, Preservation Methods And Holding Times Dr. Sameer Shadeed

25. Containers, Preservation Methods And Holding Times Dr. Sameer Shadeed

26. Occupational Health and Safety • There are many hazards to be aware of when working in any field of environment. It is recommended that a specific safety plan be developed for each monitoring plan. The safety plan should be developed to address risks and may include such things as: • Hazard identification, risk assessment and hazard control measures. Typical hazards in sampling include: • vehicle breakdown or accident; exposure to hazardous substances; temperature hazards, typically sunburn and heatstroke; working in, over or adjacent to water; poisonous animals (spiders, snakes) and plants • Actions to be undertaken to remove, reduce or control risk • Emergency procedures and information such as location of nearest medical facility • When conducting a sampling event, the right safety equipment will make the task safer. This equipment can be preventative or provide assistance in the case of an incident Dr. Sameer Shadeed

27. Collection of Samples and Sampling Modes • It is important when undertaking sampling that the sampling equipment is inert, that is, it does not cause contamination or interference with the sample • There are different sampling modes: • Surface samples: When the water body is shallow and well mixed, sub-surface water sampling is generally adequate. Sub-surface samples usually taken by hand from approximately 30 cm depth, with care taken to ensure no floating films or organic material are collected unless they are of specific interest. Where it is impractical or unsafe to sample by hand, a sampling rod can be used Dr. Sameer Shadeed

28. Collection of Samples and Sampling Modes • Sampling at depths: When samples are required from particular depths, such as for depth profiling, specific equipment is required Van Dorn samplers with cup ends set open Dr. Sameer Shadeed

29. Collection of Samples and Sampling Modes • Automatic samplers: Automatic samplers can be used to take discrete, continuous or composite samples • Grab samples: Grab samples are discrete samples that are taken at a location to provide a “snapshot” of the water quality characteristics at that time. For the purposes of quantifying water or wastewater constituents, grab samples will show the concentrations at that location and time of sampling. They will not provide any information about the concentrations outside that point in time. As such, if grab samples are employed, a high number of samples may be required to show the nature of change over time Dr. Sameer Shadeed

30. Collection of Samples and Sampling Modes • Composite samples: Composite samples are those collected through mixing multiple grab samples to obtain a single mixed sample. Compositing samples can increase the temporal and spatial extent of sampling, without increasing the number of samples or sampling and analysis costs. These types of samples are used when the average water quality characteristics are of interest over a given period of time or volume of flow. They may be more appropriate than grab samples when the distribution of constituents within the waste stream is random or when the variability within that stream is low Dr. Sameer Shadeed

31. Sample Identification, Transport and Storage • Labeling and identification: Samples need to be labeled so they can be readily identified at all times. Sample containers should be marked in such a way that they can be clearly identified and distinguished from other samples in the laboratory. Without appropriate labeling, all samples may look alike. Labels will need to be durable. Most samples will be preserved in ice so labels which will not come off when wet need to be used and the ink used will need to be insoluble in water. It is important to take care when packing samples, as samples are often subject to vibration during transport causing identification to rub off or become illegible • Labels may contain: date and time of sampling; location and name of sampling site; job or project number; name of sampler Dr. Sameer Shadeed

32. Sample Identification, Transport and Storage • Chain of Custody: Chain of Custody procedures and documentation demonstrate sample control. This gives confidence that the sample integrity has not been compromised and imperative if the samples are to be used in legal proceedings or if there is any suspicion that the samples might be tampered with at any stage of the process. The Chain of Custody documentation is a record used to trace possession and handling of a sample from the time of collection through analysis, reporting and disposal. The basis of Chain of Custody control is that a sample is always in someone’s custody and as such they are responsible for it. It is important to realize that couriers will often not recognize the contents of a sample container, but only take responsibility for the container itself. As such, the item (e.g., Esky) should be secured with tape so that it would be obvious if the items had been tampered with Dr. Sameer Shadeed

33. Chain of Custody Form (Example) Source, EPA Guidelines: Water and wastewater sampling Dr. Sameer Shadeed

34. Sample Identification, Transport and Storage • Transport and storage: During sample transport and storage it is vital that all procedures are followed to ensure that samples are not significantly altered in condition and are in a state fit for analysis at the laboratory. Contamination of samples can easily occur during transport due to container cross-contamination, packaging material or chilling products. During sample storage, degradation can occur due to lack of appropriate preservation, inappropriate storage conditions, excessive storage times and sample cross-contamination Dr. Sameer Shadeed

35. Sample Identification, Transport and Storage • Transport and storage: The key aspects of effective transport and storage are to: • Ensure samples are appropriately packed to avoid breakage and cross-contamination • Reduce sample degradation through appropriate preservation • Ensure time between sampling and analyzing does not exceed holding time • Sample containers should be sealed, carefully packed with an appropriate packing material, chilled or frozen (as required) and transported in an appropriate cooler (Esky) or Fridge Dr. Sameer Shadeed

36. Duration of Sampling • For regulatory monitoring, sampling will generally be ongoing to show continued compliance with criteria, or to monitor the ongoing influence of discharges on the receiving environment • Campaign monitoring or pilot studies should be considered when the variability of a wastewater stream or receiving environment is uncertain • A pilot study of high frequency discrete and/or composite sampling will provide information regarding the variability in the wastewater stream due to random and systematic influences • Based on an understanding of the results of the pilot study, a more targeted, cost-effective ongoing monitoring plan that will adequately characterize the water can be developed Dr. Sameer Shadeed

37. Sampling Locations • The design of a sampling plan to monitor water or wastewater composition should ensure samples are collected at sites and times that provide a representative sample, thus providing an accurate description of the overall quality of the wastewater stream • Additionally, sampling sites should be located in areas that are safe to access, accessible under all conditions of flow and discharge, be well mixed to ensure a homogenous sample is collected and be easily identifiable for later sampling • Permanent sampling locations should be established in any sampling environment to ensure that representative samples can be compared over time Dr. Sameer Shadeed

38. Determine Impacts on Receiving Waters • In the case of examining the effect of a point source discharge, sites should be arranged in such a way that the end-of-pipe, and upstream and downstream of the discharge water is sampled • The degree of mixing within the water body will determine the proximity of sites to each other, where mixing is strong (the water is homogenous) sites may be spread further apart • As a minimum, sampling the effects of a point source discharge should include the following sample locations: • End-of-pipe samples to characterize the discharge • In the receiving water upstream of the point of entry • In the water body at the point of entry • Multiple samples at progressive distances downstream from the point of entry Dr. Sameer Shadeed

39. Wastewater Sampling • The number of samples required to determine the composition of wastewater will depend upon the accuracy/precision required from the study and the variability of the stream • Generally, grab samples can be used where the analyte of interest is not expected to vary greatly over time • Sampling of wastewater may be undertaken in tanks, drums, pipes, lagoons, drains, open channels and from taps or valves • Wastewater in pipes will often exhibit laminar flow and samples taken from taps can be strongly influenced by boundary effects, which may not produce a representative sample • In the case of in-pipe laminar flow, the sampling location should be situated downstream of a restriction or obstacle which creates turbulence and mixing in the wastewater stream Dr. Sameer Shadeed

40. Taking Samples-General Procedures Sample bottles shall be labeled indelibly prior to sampling with a unique sample number, the location, date and analyses required Sample directly into the sampling bottle or jar unless a mixed sample is necessary, in which case ensure that the larger mixing container has been prepared in the same manner as the sampling container It is necessary that the person taking the samples use their discretion while collecting, so as not to take a non-representative sample. When sampling waters, flowing or well mixed water is preferable to use for sampling, but this may not always be available, particularly when very still conditions cause stratification in dams or lakes. In this case, attempt to collect three equally sized samples, from the surface, mid-zone and deeper waters, mix them together and sub-sample the mixture Dr. Sameer Shadeed

41. Taking Samples-General Procedures When sampling water in streams or dams, submerge the bottle carefully. The mouth of the bottle should be held at least 10 cm below the surface Do not rinse the sampling container in the sample stream when sampling waters. If it has been correctly prepared the sample container should not contain any contaminants When sampling water bodies avoid dislodging benthic algal mats, scraping against walls or floors of water bodies, or disturbing the sediment. Care should be taken so that no larger animals or algae mats are included in the sample, unless that is what you specifically wish to sample In flowing water, always ensure that your hand is downstream of the collecting bottle's mouth and that the mouth of the bottle is facing into the current. Ensure that the sample is taken midstream Dr. Sameer Shadeed

42. Taking Samples-General Procedures When collecting bacterial samples use clean hands, disposable gloves and sterile collection procedure; that is, only break the seal just prior to collecting the sample, hold lid and bottle opening facing downwards, do not put the lid down on a surface, cap the sample immediately after collecting Record relevant details on the sampling record sheet, and also on the Chain of Custody record for samples being sent away for testing Sample bottles for nutrient analysis should be filled to the top and the last air squeezed out of the sample bottle prior to sealing, to minimize the chance of nitrogen fixation prior to testing. Samples should be chilled immediately, and stored in a freezer before dispatch to the testing laboratory in an ice-filled Esky Dr. Sameer Shadeed